Global net carbon exchange and intra‐annual atmospheric CO 2 concentrations predicted by an ecosystem process model and three‐dimensional atmospheric transport model

A generalized terrestrial ecosystem process model, BIOME‐BGC (for BIOME BioGeoChemical Cycles), was used to simulate the global fluxes of CO 2 resulting from photosynthesis, autotrophic respiration, and heterotrophic respiration. Daily meteorological data for the year 1987, gridded to 1° by 1°, were...

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Veröffentlicht in:Global biogeochemical cycles 1996-09, Vol.10 (3), p.431-456
Hauptverfasser: Hunt, E. Raymond, Piper, Stephen C., Nemani, Ramakrishna, Keeling, Charles D., Otto, Ralf D., Running, Steven W.
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Sprache:eng
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Zusammenfassung:A generalized terrestrial ecosystem process model, BIOME‐BGC (for BIOME BioGeoChemical Cycles), was used to simulate the global fluxes of CO 2 resulting from photosynthesis, autotrophic respiration, and heterotrophic respiration. Daily meteorological data for the year 1987, gridded to 1° by 1°, were used to drive the model simulations. From the maximum value of the normalized difference vegetation index (NDVI) for 1987, the leaf area index for each grid cell was computed. Global NPP was estimated to be 52 Pg C, and global R h was estimated to be 66 Pg C. Model predictions of the stable carbon isotopic ratio 13 C/ 12 C for C 3 and C 4 vegetation were in accord with values published in the literature, suggesting that our computations of total net photosynthesis, and thus NPP, are more reliable than R h . For each grid cell, daily R h was adjusted so that the annual total was equal to annual NPP, and the resulting net carbon fluxes were used as inputs to a three‐dimensional atmospheric transport model (TM2) using wind data from 1987. We compared the spatial and seasonal patterns of NPP with a diagnostic NDVI model, where NPP was derived from biweekly NDVI data and R h was tuned to fit atmospheric CO 2 observations from three northern stations. To an encouraging degree, predictions from the BIOME‐BGC model agreed in phase and amplitude with observed atmospheric CO 2 concentrations for 20° to 55°N, the zone in which the most complete data on ecosystem processes and meteorological input data are available. However, in the tropics and high northern latitudes, disagreements between simulated and measured CO 2 concentrations indicated areas where the model could be improved. We present here a methodology by which terrestrial ecosystem models can be tested globally, not by comparisons to homogeneous‐plot data, but by seasonal and spatial consistency with a diagnostic NDVI model and atmospheric CO 2 observations.
ISSN:0886-6236
1944-9224
DOI:10.1029/96GB01691